JP6149897B2 - Two-member connection structure - Google Patents

Description

  The present invention relates to a connection structure that connects a first member having a cylindrical portion and a second member having a columnar portion.

  Conventionally, in various machines, the first member having a cylindrical portion and the second member having a cylindrical portion are joined to each other in a state where the cylindrical portion is fitted in the cylindrical portion. There is a place for connecting the first member and the second member. For example, Patent Document 1 below discloses a manual transmission for a vehicle, and links a shift and select shaft, which is a component of the manual transmission, with a shift cable having one end connected to the operation member. In order to achieve this, a cable end (connecting eye member) provided at the other end of the shift cable is connected to an outer lever extending in the radial direction from the tip of the shift and select shaft. The cable end and the outer lever are connected to the cylindrical portion of the cable end in a state where the cylindrical portion (outer lever pin) fixed to the outer lever is fitted into the cylindrical portion. It is connected.

JP 2008-045594 A

  The connecting structure for connecting the first member having the cylindrical portion and the second member having the cylindrical portion as described above usually needs to be connected so as not to come off, but on the other hand, for repair or maintenance, etc. When it is necessary to remove two members, it is desirable that the two members can be easily attached and detached. The present invention has been made in view of such circumstances, and in the connection structure of the first member having the cylindrical portion and the second member having the columnar portion, the two members are securely connected while being removed. The task is to improve workability.

In order to solve the above problems, the connection structure of the present invention is
A pair of slots that are formed in the cylindrical portion so as to extend in the circumferential direction, and are formed at positions facing each other across the axis of the cylindrical portion;
A circumferential groove formed on the outer periphery of the cylindrical portion;
With the pair of slots and the circumferential groove aligned, the cylindrical part and the column part can be rotated relative to each other by being inserted from the pair of slots and partially fitted into the circumferential groove. And a coupler that is coupled to the
The coupler is
One wire rod is formed by bending, and (A) a pair of engaging portions that extend in parallel with each other and engage with a pair of slots, respectively, and (B) one that is positioned diagonally to each other A portion that connects one end of the pair of engaging portions and the other end of the pair of engaging portions, from one end of the pair of engaging portions to the other end of the pair of engaging portions A connecting portion extending toward the other side and connecting one end of the pair of engaging portions and the other end of the pair of engaging portions so as to surround the other of the pair of engaging portions; An extension portion that linearly extends from one other end of the pair of engagement portions toward the other end of the pair of engagement portions,
The connection structure is
The first member and the second member can be removed by rotating the coupler with respect to the cylindrical portion while being elastically deformed so as not to engage the circumferential groove.
The coupler is
Even if the extension portion of the coupler is engaged with one of the pair of slots due to rotation with respect to the cylindrical portion, the length of the extension portion does not enter the circumferential groove. It is formed.

  When the coupler is rotated to disconnect the first member from the second member, the coupler rotates too much with respect to the cylindrical portion, and the tip of the extension portion enters the circumferential groove. If the length is such that the tip of the extending portion of the coupler enters the space formed by the inner peripheral surface of the cylindrical portion (the portion where no slot is formed) and the circumferential groove of the cylindrical portion. Therefore, it becomes very difficult to remove the connection between the first member and the second member. In the connection structure of the present invention, since the coupler is formed in such a length that the tip of the extending portion does not enter the circumferential groove, the above situation does not occur.

It is a perspective view of the transmission for vehicles in which the connection structure which is an example of the claimable invention is adopted. In FIG. 1, it is a figure which expands and shows the circumference | surroundings of the connection structure which is an Example of claimable invention. It is a figure which shows the state which cancelled | released the connection of the connection structure which is an Example of claimable invention. It is a perspective view which expands further and shows the connection structure which is an Example of claimable invention. It is plane sectional drawing of the connection structure which is an Example of claimable invention. FIG. 6 is a plan sectional view showing a state where two members can be removed by rotating the coupler shown in FIG. 5. It is the (a) perspective view and (b) plane sectional view which show the connection structure of a comparative example. (A) In the connection structure which is an Example of claimable invention, and (b) the connection structure of a comparative example, it is a plane sectional view showing the state where the coupler rotated too much.

  Hereinafter, as an embodiment for carrying out the present invention, an embodiment of the present invention will be described in detail with reference to the drawings. In addition, this invention is not limited to the following Example, It can implement in the various aspect which gave various change and improvement based on the knowledge of those skilled in the art.

  FIG. 1 shows a vehicular transmission 10 that employs a connecting structure according to an embodiment of the present invention. The vehicle transmission device 10 is a so-called automatic transmission, and includes a transaxle 12 including an automatic transmission, a selector 14 as an operation member operated by a driver to switch the traveling state of the vehicle, and the transaxle 12 A select cable 16 for linking the selector 14 is included.

  In the selector 14, the select lever 20 is positioned in one of the ranges of P (parking), R (reverse), N (neutral), and D (drive) by the operation of the driver. The state from the input to the output of the driving force in the automatic transmission of the transaxle 12 is mechanically switched via the select cable 16 in accordance with the range position of the select lever 20. Although the detailed description and illustration are omitted, the transaxle 12 is configured such that the output shaft (drive side) of the automatic transmission is mechanically driven by the rotation of a select shaft 26 as an input shaft rotatably held in the housing 24. Fixed state (P range), a state where the input shaft and the output shaft are connected so as to reverse the vehicle (R range), a state where no force is transmitted between the input shaft and the output shaft (N range) ) And the state where the automatic transmission function is activated (D range).

  The connecting structure of this embodiment is employed at a location where the select cable 16 and the select shaft 26 are connected. First, as shown in FIGS. 2 and 3, the select shaft 26 is rotatably held by the housing 24 with one end side extending to the outside of the housing 24. An outer lever 30 is fixed to one end of the select shaft 26 so as to extend in a direction perpendicular to the select shaft 26. The outer lever 30 has an outer lever pin 32 erected on the distal end side.

  On the other hand, the select cable 16 extending from the selector 14 has a cable end 40 fixed to the tip thereof. The cable end 40 has a generally annular main body portion 42 and a cylindrical portion 44 protruding upward from the main body portion 42. The outer diameter of the cylindrical portion 44 is smaller than the outer diameter of the main body portion 42 and is formed in a stepped shape. The cylindrical portion 44 and the main body portion 42 form a through hole 46 that penetrates in the vertical direction.

  Then, in a state where the outer lever pin 32 is inserted into the through hole 46 of the cable end 40, the outer lever pin 32 and the cylindrical portion 44 of the cable end 40 are relatively rotated by a clip 50 serving as a connector described in detail later. Combined as possible. That is, the outer lever 30 and the cable end 40 are connected. When the selector 14 is operated by the driver, the select cable 16 is pulled or pushed by the operation of the select lever 20. The outer lever pin 32 is operated together with the cable end 40 by the operation of the select cable 16. That is, the outer lever 30 is rotated, and the select shaft 26 is rotated around the axis. As described above, the state in the automatic transmission is switched according to the rotational position of the select shaft 26.

  The connecting structure according to the present invention combines the cylindrical portion 44 of the cable end 40 and the outer lever pin 32 as a columnar portion provided in the outer lever 30, so that the cable end 40 and the second member as the first member are combined. The outer lever 30 is connected. The connecting structure will be described in detail with reference to the perspective view of FIG. 4 and the plan sectional view of FIG. 4 and 5 show a state where the cable end 40 and the outer lever 30 are firmly connected by the connecting structure of the present invention.

  First, a pair of slots 60 and 62 are formed in the cylindrical portion 44 of the cable end 40. Each of the pair of slots 60 and 62 extends in the circumferential direction to the cylindrical portion 44 and is formed at a position facing each other across the axis of the cylindrical portion 44. On the other hand, the outer lever pin 32 is formed with a circumferential groove 64 that goes around the outer periphery. In the state in which the cable end 40 is fitted to the outer lever pin 32, the height of the pair of slots 60, 62 and the circumferential groove 64 is the same. Then, when the clip 50 is inserted from the pair of slots 60 and 62 and fitted into the circumferential groove 64, the cylindrical portion 44 and the outer lever pin 32 are coupled and are not detached.

  The clip 50 is formed by bending one wire. The clip 50 extends in parallel with each other and engages with a pair of slots 60 and 62, respectively, and a connection portion 74 that connects the pair of engagement portions 70 and 72. The second engaging portion 72 is formed in a shape having an extending portion 76 extending from the end of the second engaging portion 72. In the following description, the pair of engaging portions 70 and 72 may be referred to as “first engaging portion 70” and “second engaging portion 72”.

  The connection portion 74 of the clip 50 connects one end (the lower end in FIG. 5) of the first engagement portion 70 and one end (the upper end in FIG. 5) of the second engagement portion 72. From one end of the portion 72, it extends substantially at right angles toward the first engagement portion 70, and extends to one end of the first engagement portion 70 so as to surround the first engagement portion 70. Specifically, the connection portion 74 of the clip 50 extends from one end of the second engagement portion 72 toward the other end (the upper end in FIG. 5) of the first engagement portion 70, and the first engagement portion 70. The second engaging portion side connecting portion 80 extending beyond the other end of the first engaging portion, and the first engaging portion side extending in parallel with the second engaging portion side connecting portion 80 from one end of the first engaging portion 70 The connection portion 82 and the intermediate portion 84 that connects the tip of the second engagement portion side connection portion 80 and the tip of the first engagement portion side connection portion 82 are formed. As shown in FIG. 4, the intermediate portion 84 is formed in a shape that protrudes upward, specifically, in the axial direction of the cylindrical portion 44, and functions as a protruding portion. The extending portion 76 extends from the other end (the lower end in FIG. 5) of the second engaging portion 72 toward one end of the first engaging portion 70 and extends to the tip of the first engaging portion connecting portion 82. It is formed in an extended length.

  That is, in the clip 50 formed in the shape as described above, the first engaging portion 70 enters the slot 60 and engages with the circumferential groove 64, and the second engaging portion 72 enters the slot 62 and circularly. The peripheral groove 64 is engaged. Therefore, the outer lever pin 32 and the cylindrical portion 44 are prohibited from relative movement in the axial direction and allowed to rotate relative to each other. That is, the outer lever pin 32 and the cylindrical portion 44 are coupled by the clip 50 so as to be relatively rotatable. Therefore, this connection structure includes a pair of slots 60 and 62 formed in the cylindrical portion 44, a circumferential groove 64 formed in the outer lever pin 32, and the clip 50, and the cable as the first member The end 40 is connected to the outer lever 30 as the second member.

  Next, release of the connection of this connection structure, that is, removal of the cable end 40 and the outer lever 30 will be described. When removing the cable end 40 and the outer lever 30, the clip 50 is rotated in any one of the circumferential directions of the cylindrical portion 44. FIG. 6 shows a state rotated in the direction of the arrow shown in FIGS. In this state, the clip 50 is such that each of the pair of engaging portions 70 and 72 rides on the outer peripheral surface of the cylindrical portion 44, comes out of the circumferential groove 64, and engages with the circumferential groove 64. It is in a state that does not. That is, the outer lever pin 32 and the cylindrical portion 44 can move relative to each other in the axial direction, and can be removed by lifting the cable end 40 together with the clip 50 from the outer lever 30.

  FIG. 7 shows a connection structure for comparison with the present connection structure. The connection structure of the comparative example is different in the shape of the clip 100 from the clip 50 of the connection structure of the present embodiment. The clip 100 has a shape similar to that of the clip 50, and is formed into a shape having a pair of engaging portions 102 and 104, a connecting portion 106, and an extending portion 108. However, the clip 100 is not formed with a protruding portion at the connection portion 106, and is formed by bending one wire rod on one plane. Further, in the clip 100, the length of the extended portion 108 is shorter than the extended portion 76 of the clip 50 included in the connection structure of this embodiment.

  In the connection structure of this comparative example, when the cable end 40 and the outer lever 30 are removed, the clip 100 is plastically deformed so as to widen the distance between the pair of engaging portions 102 and 104, and the cylindrical portion 44. It was removed from. Therefore, the clip 100 cannot be reused, and when the cable end 40 and the outer lever 30 are connected again, it is necessary to replace the clip 100 with a new one.

  As described above, the connection structure of this embodiment rotates the clip 50 relative to the cylindrical portion 44 so that the clip 50 does not engage with the circumferential groove 64, so that the cable end 40 and the outer lever 30 can be removed. In the connection structure of the comparative example described above, a case where a method of removing the cable end 40 and the outer lever 30 by rotating the clip with respect to the cylindrical portion 44 is considered as in the connection structure of the present embodiment. As described above, since the clip 100 is formed by bending a single wire in a single plane as described above, the connection structure of the comparative example does not have a place where an operator presses or grips it. It is relatively difficult to rotate the clip 100 until it does not engage the groove 64.

  Moreover, even if the clip 10 rotates, there is a possibility that the clip 10 will rotate too much beyond the state where it does not engage with the circumferential groove 64. For example, when the clip 100 has rotated too much with respect to the cylindrical portion 44, as shown in FIG. 8B, the tip of the extending portion 108 is connected to the inner peripheral surface (slot 60) of the cylindrical portion 44. , 62 are not formed) and the circumferential groove 64 of the outer lever pin 32 may enter the space formed. In such a state, it becomes difficult to rotate the clip 100 in a direction to return it to the original state or to remove it by plastic deformation.

  On the other hand, in the connection structure of the present embodiment, since the clip 50 has the protruding portion (intermediate portion 84), the operator can rotate the clip 50 so as to press the protruding portion. Thus, the cable end 40 and the outer lever 30 can be easily removed. Further, the clip 50 has a low rigidity of the connecting portion 74 due to the presence of the protruding portion. More specifically, as shown in FIG. 6, the clip 50 is elastically deformed so that the intermediate portion 84 is twisted, and the interval between the pair of engaging portions 70 and 72 is widened. Can be rotated.

  Furthermore, in the connection structure of the present embodiment, even when the clip 50 is rotated too much with respect to the cylindrical portion 44, as shown in FIG. (If it is reverse rotation, it engages with the slot 62) so that the tip of the extending portion 76 does not enter the circumferential groove 64. Therefore, in the connection structure of the present embodiment, when the clip 50 is rotated too much with respect to the cylindrical portion 44, the clip 50 is easily rotated in the reverse direction, so that the clip 50 becomes the circumferential groove 64. It is possible to return to a non-engaged state.

  In addition, since the location where the cable end 40 and the outer lever 30 are connected is located in the engine room, there are various devices around. Therefore, the cable end 40 and the outer lever 30 may have to be removed not only when repairing the transmission 10 for this vehicle but also when repairing the devices existing around them. And since the location where the cable end 40 and the outer lever 30 are connected is in such a position, the operation of removing the cable end 40 and the outer lever 30 is a relatively difficult operation. However, according to the connection structure of the present embodiment, it is possible to improve the workability of the work of removing the cable end 40 and the outer lever 30.

  Incidentally, the connection structure of the present embodiment has been adopted at a position where the automatic transmission for a vehicle and the select cable 16 extending from the selector 14 are connected. For example, a manual transmission and an operation lever (for the manual transmission) ( It is also possible to employ the shift cable and the select cable extending from the shift lever) at a location where they are connected. Furthermore, the present invention is not limited to vehicles, and can be employed in various work machines.

  10: Vehicle transmission 12: Transaxle 14: Selector [operation member] 16: Select cable 20: Select lever 26: Select shaft [input shaft] 30: Outer lever [second member] 32: Outer lever pin [cylindrical portion] 40: Cable end [first member] 42: Main body portion 44: Cylindrical portion 46: Through hole 50: Clip [connector] 60, 62: Pair of slots 64: Circumferential groove 70: First engaging portion 72 : Second engaging portion 74: connecting portion 76: extending portion 80: second engaging portion side connecting portion 82: first engaging portion side connecting portion 84: intermediate portion (protruding portion)

Claims (4)

A connection structure for connecting a first member having a cylindrical part and a second member having a columnar part in a state where the columnar part is fitted into the cylindrical part,
A pair of slots that are formed in the cylindrical portion so as to extend in the circumferential direction, and are formed at positions facing each other across the axis of the cylindrical portion;
A circumferential groove formed on the outer periphery of the cylindrical portion;
In a state where the pair of slots and the circumferential groove are aligned with each other, the cylindrical portion and the column are inserted into the circumferential groove by being inserted from the pair of slots. And a coupler that couples the parts to each other so as to be relatively rotatable,
The coupler is
One wire rod is formed by bending, and (A) a pair of engaging portions that extend in parallel with each other to engage with the pair of slots, and (B) are positioned diagonally to each other. A portion connecting one end of the pair of engaging portions and the other end of the pair of engaging portions; and from the one end of the pair of engaging portions to the pair of engaging portions One end of the pair of engaging portions and the other end of the pair of engaging portions so as to extend toward the other other end of the pair and surround the other of the pair of engaging portions. A connecting portion to be connected; and (C) an extending portion linearly extending from one other end of the pair of engaging portions toward the other end of the pair of engaging portions. And
The connection structure is
The first member and the second member can be removed by rotating the coupler with respect to the cylindrical portion while being elastically deformed so as not to engage with the circumferential groove. Yes,
The coupler is
Even when the extension portion of the coupler is engaged with one of the pair of slots due to excessive rotation with respect to the cylindrical portion, the tip of the extension portion enters the circumferential groove. A connecting structure characterized in that it is formed to have no length. The connecting portion of the coupler is
The connection structure according to claim 1, further comprising a protruding portion formed so as to protrude in a direction intersecting with one plane including the pair of engaging portions and the extending portion.   The connection structure according to claim 2, wherein the protruding portion is formed to protrude in an axial direction of the cylindrical portion. The connection structure is
One component of a vehicle transmission, which is provided at one end of a cable connected to the operation member, is connected to an input shaft that is rotatably provided and an operation member of the transmission. For connecting a cable end as the first member and a lever as the second member extending from the input shaft in the radial direction of the input shaft,
The cylindrical portion is provided at the cable end so as to extend in a direction crossing the cable;
The cylindrical portion is erected at the tip of the lever;
The connection structure according to any one of claims 1 to 3, wherein the coupler is configured to couple the cylindrical portion of the cable end and the column portion of the lever.

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